Biomonitoring the Health of Coastal Marine Ecosystems – The Roles and Challenges of Microscale Toxicity Tests

Abstract

Coastal marine ecosystems in many parts of the world are under unrelenting stress caused by urban development, hazardous or toxic substances, overfishing, habitat destruction, the introduction of exotic species and natural toxins. Biomonitoring plays a vital role in governmental and industrial strategies to identify, assess, control and reduce these problems. Sensitive and practical techniques in biomonitoring are needed in all of the strategic approaches – from toxic chemical rating and classification, to pollution source control, status and trends monitoring, and assessments of “marine ecosystem health”. Due to the shear magnitude and scope of the challenge, biomonitoring coastal ecosystems demands new and innovative approaches that are relatively easy and cheap to deploy and that provide timely and accessible information to environmental managers and policy makers. This paper explores recent developments in microscale toxicity testing – a branch of aquatic toxicology involving the discovery and application of small-scale, innovative, sensitive, practical, inexpensive and frequently automated biological techniques. Highlights of a recent unique synthesis (Wells et al., 1998) are given, describing microscale tests at various biological and phylogenetic levels. Many of these tests are marine and focus on gametes, embryos and other young life stages. They can be utilized in the field ( in vivo), with field collected samples, and in the laboratory. Their low cost, sensitivity, practicality and speed are their strengths, and commercial test kits have been developed as a result. But being largely “single-species” and sub-individual-level biomonitors, do such microscale tests provide information directly useful to protecting vital ecosystem processes? Indeed, how can this question be addressed? The needs and challenges of matching the most promising of the microscale tests with higher level (population, community, ecosystem) measurements to protect habitats and biodiversity are discussed. Improving marine biomonitoring and protecting coastal ecosystem health demands such new techniques within the context of new paradigms and rigorous approaches for their application.